SBFS023C June 2003 – December 2016 SRC4190
PRODUCTION DATA.
- 1 Features
- 2 Applications
- 3 Description
- 4 Revision History
- 5 Pin Configuration and Functions
- 6 Specifications
- 7 Detailed Description
-
8 Application and Implementation
- 8.1 Application Information
- 8.2 Typical Application
- 9 Power Supply Recommendations
- 10Layout
- 11Device and Documentation Support
- 12Mechanical, Packaging, and Orderable Information
Package Options
Mechanical Data (Package|Pins)
- DB|28
Thermal pad, mechanical data (Package|Pins)
Orderable Information
6 Specifications
6.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)(1)| MIN | MAX | UNIT | |
|---|---|---|---|
| Supply voltage, VDD | –0.3 | 4 | V |
| Supply voltage, VIO | –0.3 | 4 | V |
| Digital input voltage | –0.3 | 4 | V |
| Operating temperature | –45 | 85 | °C |
| Storage temperature, Tstg | –65 | 150 | °C |
(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
6.2 ESD Ratings
| VALUE | UNIT | |||
|---|---|---|---|---|
| V(ESD) | Electrostatic discharge | Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001(1) | ±2000 | V |
| Charged-device model (CDM), per JEDEC specification JESD22-C101(2) | ±1500 | |||
(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
6.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)| MIN | NOM | MAX | UNIT | ||
|---|---|---|---|---|---|
| VDD | VDD supply voltage | 3 | 3.3 | 3.6 | V |
| VIO 1.8-V supply voltage | 1.65 | 1.8 | 1.95 | V | |
| VIO 3.3-V supply voltage | 3 | 3.3 | 3.6 | V | |
| Operating temperature | –45 | 85 | °C | ||
6.4 Thermal Information
| THERMAL METRIC(1) | SRC4190 | UNIT | |
|---|---|---|---|
| DB (SSOP) | |||
| 28 PINS | |||
| RθJA | Junction-to-ambient thermal resistance | 77.8 | °C/W |
| RθJC(top) | Junction-to-case (top) thermal resistance | 37.6 | °C/W |
| RθJB | Junction-to-board thermal resistance | 38.4 | °C/W |
| ψJT | Junction-to-top characterization parameter | 8.8 | °C/W |
| ψJB | Junction-to-board characterization parameter | 38.1 | °C/W |
(1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report.
6.5 Electrical Characteristics
TA = 25°C, VDD = 3.3 V = VIO = 3.3 V (unless otherwise noted).| PARAMETER | TEST CONDITIONS | MIN | TYP | MAX | UNIT | ||
|---|---|---|---|---|---|---|---|
| DYNAMIC PERFORMANCE(1) | |||||||
| Resolution | 24 | Bits | |||||
| fSIN | Input sampling frequency | 4 | 212 | kHz | |||
| fSOUT | Output sampling frequency | 4 | 212 | kHz | |||
| Input:Output sampling ratio | Upsampling | 1:16 | |||||
| Downsampling | 16:1 | ||||||
| Dynamic range | BW = 20 Hz to fSOUT / 2, –60-dBFS input, fIN = 1 kHz, Unweighted (add 3 dB for A‑weighted result) |
44.1 kHz:48 kHz | 125 | dB | |||
| 48 kHz:44.1 kHz | 125 | ||||||
| 48 kHz:96 kHz | 125 | ||||||
| 44.1 kHz:192 kHz | 125 | ||||||
| 96 kHz:48 kHz | 125 | ||||||
| 192 kHz:12 kHz | 125 | ||||||
| 192 kHz:32 kHz | 125 | ||||||
| 192 kHz:48 kHz | 125 | ||||||
| 32 kHz:48 kHz | 125 | ||||||
| 12 kHz:192 kHz | 125 | ||||||
| Total harmonic distortion + noise |
BW = 20 Hz to fSOUT / 2, 0-dBFS input, fIN = 1 kHz, Unweighted |
44.1 kHz:48 kHz | –125 | dB | |||
| 48 kHz:44.1 kHz | –125 | ||||||
| 48 kHz:96 kHz | –125 | ||||||
| 44.1 kHz:192 kHz | –125 | ||||||
| 96 kHz:48 kHz | –125 | ||||||
| 192 kHz:12 kHz | –125 | ||||||
| 192 kHz:32 kHz | –125 | ||||||
| 192 kHz:48 kHz | –125 | ||||||
| 32 kHz:48 kHz | –125 | ||||||
| 12 kHz:192 kHz | –125 | ||||||
| Interchannel gain mismatch | 0 | dB | |||||
| Interchannel phase deviation | 0 | ° | |||||
| Mute attenuation | 24-bit word length, A-weighted | –128 | dB | ||||
| DIGITAL INTERPOLATION FILTER | |||||||
| Passband | 0.4535 × fSIN | Hz | |||||
| Passband ripple | ±0.007 | dB | |||||
| Transition band | 0.4535 × fSIN | 0.5465 × fSIN | Hz | ||||
| Stop band | 0.5465 × fSIN | Hz | |||||
| Stop band attenuation | –125 | dB | |||||
| Normal group delay (LGRP = 0) | 102.53125 / fSIN | s | |||||
| Low group delay (LGRP = 1) | 70.53125 / fSIN | s | |||||
| DIGITAL DECIMATION FILTER | |||||||
| Passband | 0.4535 × fSOUT | Hz | |||||
| Passband ripple | ±0.008 | dB | |||||
| Transition band | 0.4535 × fSOUT | 0.5465 × fSOUT | Hz | ||||
| Stop band | 0.5465 × fSOUT | Hz | |||||
| Stop band attenuation | –125 | dB | |||||
| Group delay | 36.46875 / fSOUT | s | |||||
| DIGITAL I/O | |||||||
| VIH | High-level input voltage | 0.7 × VIO | VIO | V | |||
| VIL | Low-level input voltage | 0 | 0.3 × VIO | V | |||
| IIH | High-level input current | 0.5 | 10 | µA | |||
| IIL | Low-level input current | 0.5 | 10 | µA | |||
| VOH | High-level output voltage | IO = –4 mA | 0.8 × VIO | VIO | V | ||
| VOL | Low-level output voltage | IO = 4 mA | 0 | 0.2 × VIO | V | ||
| CIN | Input capacitance | 3 | pF | ||||
| POWER SUPPLY | |||||||
| VDD | VDD operating voltage | 3 | 3.3 | 3.6 | V | ||
| VIO | VIO operating voltage | 1.65 | 3.3 | 3.6 | |||
| IDD | VDD supply current | VDD = VIO = 3.3 V, RST = 0, No clocks, fSIN = 192 kHz, fSOUT = 192 kHz |
Power down | 100 | µA | ||
| Dynamic | 66 | mA | |||||
| IIO | VIO supply current | VDD = VIO = 3.3 V, RST = 0, No clocks, fSIN = 192 kHz, fSOUT = 192 kHz |
Power down | 100 | µA | ||
| Dynamic | 2 | mA | |||||
| PD | Power dissipation | VDD = VIO = 3.3 V, RST = 0, No clocks, fSIN = 192 kHz, fSOUT = 192 kHz |
Power down | 660 | µW | ||
| Dynamic | 225 | mW | |||||
(1) Dynamic performance measured with an Audio Precision System Two Cascade or Cascade Plus.
6.6 Switching Characteristics
over operating free-air temperature range (unless otherwise noted)| PARAMETER | TEST CONDITIONS | MIN | MAX | UNIT | |
|---|---|---|---|---|---|
| REFERENCE CLOCK TIMING | |||||
| RCKI frequency(1)(2) | 128 × fSMIN | 50 | MHz | ||
| tRCKIP | RCKI period | 20 | 1 / (128 × fSMIN) | ns | |
| tRCKIH | RCKI pulse width HIGH | 0.4 × tRCKIP | ns | ||
| tRCKIL | RCKI pulse width LOW | 0.4 × tRCKIP | ns | ||
| RESET TIMING | |||||
| tRSTL | RST pulse width LOW | 500 | ns | ||
| INPUT SERIAL PORT TIMING | |||||
| tLRIS | LRCKI to BCKI setup time | 10 | ns | ||
| tSIH | BCKI pulse width HIGH | 10 | ns | ||
| tSIL | BCKI pulse width LOW | 10 | ns | ||
| tLDIS | SDIN data setup time | 10 | ns | ||
| tLDIH | SDIN data hold time | 10 | ns | ||
| OUTPUT SERIAL PORT TIMING | |||||
| tDOPD | SDOUT data delay time | 10 | ns | ||
| tDOH | SDOUT data hold time | 2 | ns | ||
| tSOH | BCKO pulsewidth HIGH | 10 | ns | ||
| tSOL | BCKO pulse width LOW | 5 | ns | ||
| TDM MODE TIMING | |||||
| tLROS | LRCKO setup time | 10 | ns | ||
| tLROH | LRCKO hold time | 10 | ns | ||
| tTDMS | TDMI data setup time | 10 | ns | ||
| tTDMH | TDMI data hold time | 10 | ns | ||
(1) fSMIN = minimum (fSIN, fSOUT).
(2) fSMAX = maximum (fSIN, fSOUT).
6.7 Typical Characteristics
TA = 25°C, VDD = VIO = 3.3 V (unless otherwise noted).
Figure 1. FFT With 1 kHz Input Tone at 0 dBFS(12 kHz:192 kHz)
Figure 3. FFT With 1 kHz Input Tone at 0 dBFS(32 kHz:48 kHz)
Figure 5. FFT With 1 kHz Input Tone at 0 dBFS(44.1 kHz:48 kHz)
Figure 7. FFT With 1 kHz Input Tone at 0 dBFS(44.1 kHz:96 kHz)
Figure 9. FFT With 1 kHz Input Tone at 0d BFS(44.1 kHz:192 kHz)
Figure 11. FFT With 1 kHz Input Tone at 0 dBFS(48 kHz:44.1 kHz)
Figure 13. FFT With 1 kHz Input Tone at 0 dBFS(48 kHz:96 kHz)
Figure 15. FFT With 1 kHz Input Tone at 0 dBFS(48 kHz:192 kHz)
Figure 17. FFT With 1 kHz Input Tone at 0 dBFS(96 kHz:44.1 kHz)
Figure 19. FFT With 1 kHz Input Tone at 0 dBFS(96 kHz:48 kHz)
Figure 21. FFT With 1 kHz Input Tone at 0 dBFS(96 kHz:192 kHz)
Figure 23. FFT With 1 kHz Input Tone at 0 dBFS(192 kHz:12 kHz)
Figure 25. FFT With 1 kHz Input Tone at 0 dBFS(192 kHz:32 kHz)
Figure 27. FFT With 1 kHz Input Tone at 0 dBFS(192 kHz:44.1 kHz)
Figure 29. FFT With 1 kHz Input Tone at 0 dBFS(192 kHz:48 kHz)
Figure 31. FFT With 1 kHz Input Tone at 0 dBFS(192 kHz:96 kHz)
Figure 33. FFT With 20 kHz Input Tone at 0 dBFS(44.1 kHz:48 kHz)
Figure 35. FFT With 20 kHz Input Tone at 0 dBFS(48 kHz:96 kHz)
Figure 37. FFT With 80 kHz Input Tone at 0 dBFS(192 kHz:192 kHz)
Figure 39. THD+N vs Input Amplitude fIN = 1 kHz(48 kHz:44.1 kHz)
Figure 41. THD+N vs Input Amplitude fIN = 1 kHz(96 kHz:48 kHz)
Figure 43. THD+N vs Input Amplitude fIN = 1 kHz(192 kHz:44.1 kHz)
Figure 45. THD+N vs Input Frequency With0 dBFS Input = 1 kHz (48 kHz:44.1 kHz)
Figure 47. THD+N vs Input Frequency With 0 dBFS(96 kHz:48 kHz)
Figure 49. THD+N vs Input Frequency With 0 dBFS(192 kHz:44.1 kHz)
Figure 51. Linearity With fIN = 200 Hz (48 kHz:44.1 kHz)
Figure 53. Linearity With fIN = 200 Hz (96 kHz:48 kHz)
Figure 55. Linearity With fIN = 200 Hz (192 kHz:44.1 kHz)
Figure 57. Passband Ripple (48 kHz:48 kHz)
Figure 2. FFT With 1 kHz Input Tone at –60 dBFS(12 kHz:192 kHz)
Figure 4. FFT With 1 kHz Input Tone at –60 dBFS(32 kHz:48 kHz)
Figure 6. FFT With 1 kHz Input Tone at –60 dBFS(44.1 kHz:48 kHz)
Figure 8. FFT With 1 kHz Input Tone at –60 dBFS(44.1 kHz:96 kHz)
Figure 10. FFT With 1 kHz Input Tone at –60 dBFS(44.1 kHz:192 kHz)
Figure 12. FFT With 1 kHz Input Tone at –60 dBFS(48 kHz:44.1 kHz)
Figure 14. FFT With 1 kHz Input Tone at –60 dBFS(48 kHz:96 kHz)
Figure 16. FFT With 1 kHz Input Tone at –60 dBFS(48 kHz:192 kHz)
Figure 18. FFT With 1 kHz Input Tone at –60 dBFS(96 kHz:44.1 kHz)
Figure 20. FFT With 1 kHz Input Tone at –60 dBFS(96 kHz:48 kHz)
Figure 22. FFT With 1 kHz Input Tone at –60 dBFS(96 kHz:192 kHz)
Figure 24. FFT With 1 kHz Input Tone at –60 dBFS(192 kHz:12 kHz)
Figure 26. FFT With 1 kHz Input Tone at –60 dBFS(192 kHz:12 kHz)
Figure 28. FFT With 1 kHz Input Tone at –60 dBFS(192 kHz:44.1 kHz)
Figure 30. FFT With 1 kHz Input Tone at –60 dBFS(192 kHz:48 kHz)
Figure 32. FFT With 1 kHz Input Tone at –60 dBFS(192kHz:96 kHz)
Figure 34. FFT With 20 kHz Input Tone at 0 dBFS(48 kHz:44.1 kHz)
Figure 36. FFT With 20 kHz Input Tone at 0 dBFS(96 kHz:48 kHz)
Figure 38. THD+N vs Input Amplitude fIN = 1 kHz(44.1 kHz:48 kHz)
Figure 40. THD+N vs Input Amplitude fIN = 1 kHz(48 kHz:96 kHz)
Figure 42. THD+N vs Input Amplitude fIN = 1 kHz(44.1 kHz:192 kHz)
Figure 44. THD+N vs Input Frequency With 0 dBFS Input(44.1 kHz:48 kHz)
Figure 46. THD+N vs Input Frequency With 0 dBFS(48 kHz:96 kHz)
Figure 48. THD+N vs Input Frequency With 0 dBFS(44.1 kHz:192 kHz)
Figure 50. Linearity With fIN = 200 Hz (44.1 kHz:48 kHz)
Figure 52. Linearity With fIN = 200 Hz (48 kHz:96 kHz)
Figure 54. Linearity With fIN = 200 Hz (44.1 kHz:192 kHz)
Figure 56. Frequency Response With 0 dBFS Input
Figure 58. Passband Ripple (192 kHz:48 kHz)